阅读说明：本技术 具有储存及提升阴极水中氢分子浓度的装置 (Device capable of storing and improving hydrogen molecule concentration in cathode water ) 是由 徐文星 于 2020-05-26 设计创作，主要内容包括：一种具有储存及提升阴极水中氢分子浓度的装置,氢分子生成器阴极侧的盖体中心设有一阴极水出水口,该阴极水出水口设有一逆止阀,该盖体上设有一储水容器,该储水容器内部同轴心配置设有一细化套件与一导流套件,由该导流套件在该细化套件与该储水容器之间分隔出内环的溶氢水槽与外环的出水通道,电解时阴极水先向上经过细化之后,再向下导入该溶氢水槽中,未溶合的氢分子滞留于该溶氢水槽,利用氢气上升与阴极水下降所产生的相互交溶现象,使得更多氢分子溶入阴极水,再向上由该出水通道导出,待机时,该储水容器持续增压至设定压力,迫使该溶氢水槽的氢分子再溶合于阴极水,具有储存及提升阴极水中的氢分子浓度功能。(A device for storing and increasing the concentration of hydrogen molecules in cathode water is provided, a cathode water outlet is arranged in the center of a cover body on the cathode side of a hydrogen molecule generator, a check valve is arranged at the cathode water outlet, a water storage container is arranged on the cover body, a refining kit and a flow guide kit are coaxially arranged in the water storage container, an inner ring hydrogen-dissolved water tank and an outer ring water outlet channel are separated between the refining kit and the water storage container by the flow guide kit, cathode water is firstly refined during electrolysis and then is downwards guided into the hydrogen-dissolved water tank, hydrogen molecules which are not dissolved are retained in the hydrogen-dissolved water tank, more hydrogen molecules are dissolved into the cathode water by utilizing the mutual dissolution phenomenon generated by the ascending of the hydrogen and the descending of the cathode water, then the hydrogen molecules are upwards guided out from the water outlet channel, and during standby, the water storage container is continuously pressurized to a set pressure to force the hydrogen molecules dissolved in the cathode water to be dissolved in the cathode water again, has the functions of storing and improving the concentration of hydrogen molecules in cathode water.)

1. A device for storing and improving hydrogen molecule concentration in cathode water, a hydrogen molecule water generator is provided with an anode electrode plate and a cathode electrode plate which are assembled in a base body and a cover body, an ionic membrane is arranged between the anode electrode plate and the cathode electrode plate, a water inlet and outlet joint and an anode water outlet joint are arranged outside the base body, and a cathode water outlet is arranged at the center of the cover body corresponding to the cathode electrode plate, wherein:

the cover body is provided with a check valve at the cathode water outlet, the cover body is provided with a flange which is configured in a circular ring shape, a sleeve groove is arranged between the cathode water outlet and the flange of the cover body, and a water storage container is locked outside the flange;

a hydrogen molecule water outlet joint extends outwards from the center of the top surface of the water storage container, a diversion suite is arranged in the water storage container, a plurality of equally-divided positioning convex parts are arranged on the bottom surface of the water storage container, and a water outlet flow path is formed between the bottom surface of the water storage container and the top surface of the diversion suite;

the outer diameter of the diversion sleeve is smaller than the inner diameter of the water storage container, so that a water outlet channel is formed between the inner wall of the water storage container and the outer wall of the diversion sleeve, the diversion sleeve is sleeved on the flange of the cover body, a plurality of lower notches which are equally divided are arranged at the bottom of the diversion sleeve corresponding to the flange, a positioning convex rib is arranged at the top surface of the diversion sleeve corresponding to the periphery of the positioning convex parts in a surrounding manner, a plurality of upper notches which are equally divided are arranged above the positioning convex rib, cathode water is led into the water outlet channel from the lower notches and then led into the water outlet channel from the upper notches, a thinning sleeve is arranged in the diversion sleeve, a plurality of partition ribs are arranged at the upper part of the diversion sleeve in a surrounding manner and used for positioning the thinning sleeve;

the outer diameter of the refining sleeve is smaller than the inner diameter of the flow guide sleeve, so that a hydrogen dissolving water tank is formed on the inner wall of the flow guide sleeve and the outer wall of the refining sleeve, a hollow sleeve is arranged in the refining sleeve, a positioning step edge is arranged above the hollow sleeve and used for positioning the plurality of partition ribs of the flow guide sleeve, a flow space is kept between the upper part of the refining sleeve and the flow guide sleeve, and a refining material is arranged in the hollow sleeve.

2. The apparatus for storing and increasing the concentration of hydrogen molecules in cathode water according to claim 1, wherein: the outer wall of the flange is provided with an external thread, and the inner wall of the water storage container is provided with an internal thread corresponding to the external thread and used for mutually locking the seat body and the water storage container.

3. The apparatus for storing and increasing the concentration of hydrogen molecules in cathode water according to claim 1, wherein: the water inlet and outlet joint is provided with a raw water inlet joint, and a water flow starter is arranged at the raw water inlet joint and used for calculating the raw water inlet flow so as to adjust the working current.

4. The apparatus for storing and increasing the concentration of hydrogen molecules in cathode water according to claim 1, wherein: the thinning material is a hollow fiber membrane which is arranged in the hollow sleeve, a gap is kept between the thinning material and the bottom of the hollow sleeve, and the aperture of the hollow fiber membrane is 0.01-0.03 μm.

5. The apparatus for storing and increasing the concentration of hydrogen molecules in cathode water according to claim 1, wherein: the hollow sleeve is provided with a packaging material above the thinning material, the thinning material is bonded and fixed to the hollow sleeve by the packaging material, and the packaging material is implemented by one of epoxy resin or polyurethane resin.

6. The apparatus for storing and increasing the concentration of hydrogen molecules in cathode water according to claim 1, wherein: the exterior of the hollow sleeve is provided with a combination flange for combining the thinning sleeve and the hollow sleeve when the thinning sleeve and the hollow sleeve are integrally formed by injection molding.

Technical Field

The invention relates to a device for storing and improving the concentration of hydrogen molecules in cathode water, which is mainly characterized in that hydrogen gas which is not dissolved in the cathode water is retained by a closed water storage container during electrolysis, and the pressure of the water storage container is increased by using a check valve during standby to force the hydrogen molecules to be dissolved again, thereby achieving the effect of storing and improving the hydrogen molecules in the cathode water to the saturated concentration.

Background

In recent years, hydrogen molecular medicine is developed vigorously like bamboo shoots in spring after rain, and because hydrogen is odorless, colorless and free of any toxicity, is the smallest antioxidant in the universe, and has anti-inflammatory property, the hydrogen has the capability of repairing health care and beauty and injury of various human organs, various circles and medical experts are brought into clinical research, and the hydrogen molecular medicine is expected to be revolutionary.

The application of hydrogen molecules is currently divided into three modes, namely a hydrogen inhalation mode and a hydrogen inhalation mode. Secondly, a hydrogen physiological saline injection mode. And thirdly, a drinking mode of hydrogen-containing water. The hydrogen-containing drinking water mainly adopts SPE (Solid polymer electrolyte) electrolysis technology and related components to form a flowing water type electrolytic cell, and hydrogen (H) is generated at the cathode side₂) Part of the water is dissolved in the cathode water and is led out from the cathode chamber to become hydrogen molecule drinking water. Oxygen (O) is generated on the anode side₂) Part of the water is dissolved in the anode water and is discharged through a discharge device or directly connected with a waste water pipe. The discharge device makes the cathode chamber and the anode chamber of the flowing water type electrolytic cell in a pressure relief state, so that the hydrogen concentration of the hydrogen-containing water stored in the cathode chamber is dissipated and returned to zero after the hydrogen-containing water is stored for a period of time, the residual water of the cathode chamber is reduced by the design of the flowing water type electrolytic cell, and if the residual water is excessive, the hydrogen molecular concentration in the front-section cathode water cannot reach the standard when the flowing water type electrolytic cell restarts electrolysis.

In the conventional flow-type electrolytic cell, hydrogen (H) gas is generated at the cathode₂) Because of insufficient pressure and time, actually, the generated hydrogen molecules are not completely dissolved in water, and if the concentration of the hydrogen molecules in water is increased, pipelines, dissolving filter cores, pressurizing motors and other related control components must be added, however, the addition of the pipelines and the components not only causes inconvenience in space design and cost increase, but also decreases the concentration of the hydrogen molecules if the pipelines are excessively extended, which causes the hydrogen molecule content of a first cup of water (about 200CC residual water) to be insufficient and lose application value when the hydrogen molecule generator is used every day, and causes inconvenience for users and water resource waste if the first cup of water is thrown away. The above situation is a significant drawback for hydrogen molecule generators, and is a problem to be overcome in the industry.

Disclosure of Invention

While the technology for producing hydrogen gas is well established, hydrogen gas has the characteristics of being difficult to dissolve in water and store, and in order to increase the solubility of hydrogen gas and prolong the storage time, the container is sealed and the pressure is increased (1 atm greater than atmospheric pressure is 1 kg/cm)²Above) to match the gas and liquid dissolution times, forcing the hydrogen to dissolve in the water, according to henry's law: a gas with low solubility (poorly soluble) is placed in a closed container at a constant temperature simultaneously with a liquid, the gas content of which is proportional to the partial pressure of the gas above the liquid surface, as shown in fig. 1, in which: molar concentration: CM, henry's law constant: k, the gas partial pressure: p, henry's law formula: CM (molar concentration) ═ K (proportionality constant) x P (partial pressure of the gas).

According to one aspect of the present invention, there is provided a device for storing and increasing hydrogen molecule concentration in cathode water, wherein the hydrogen molecule water generator comprises a base and a cover, an anode electrode plate and a cathode electrode plate are assembled inside the base, an ionic membrane is disposed between the anode electrode plate and the cathode electrode plate, a water inlet/outlet connector and an anode water outlet connector are disposed outside the base, a cathode water outlet is disposed at a position of the cover corresponding to the center of the cathode electrode plate, a check valve is disposed at the cathode water outlet of the cover, a circular flange is disposed on the cover, a set of groove is disposed between the cathode water outlet and the flange on the cover, and a water storage container is locked outside the flange.

The center of the top surface of the water storage container extends outwards to form a hydrogen molecule water outlet joint, a diversion sleeve member is arranged in the water storage container, and a plurality of equally divided positioning convex parts are arranged on the bottom surface of the water storage container, so that a water outlet flow path is formed between the bottom surface of the water storage container and the top surface of the diversion sleeve member.

The outer diameter of the diversion sleeve is smaller than the inner diameter of the water storage container, so that a water outlet channel is formed between the inner wall of the water storage container and the outer wall of the diversion sleeve, the diversion sleeve is sleeved on the flange of the cover body, a plurality of lower equally-divided notches are formed in the bottom of the diversion sleeve corresponding to the flange, a positioning protruding rib is arranged on the top surface of the diversion sleeve corresponding to the periphery of the plurality of positioning protruding parts in a surrounding mode, a plurality of upper equally-divided notches are arranged above the positioning protruding rib, cathode water is led into the water outlet channel from the plurality of lower notches and then led into the water outlet channel from the plurality of upper notches, a thinning sleeve is arranged inside the diversion sleeve, and a plurality of partition ribs are arranged on the upper portion of the inside of the diversion sleeve in a surrounding mode and used for positioning the thinning sleeve.

The outer diameter of the refining sleeve is smaller than the inner diameter of the flow guide sleeve, so that a hydrogen dissolving water tank is formed on the inner wall of the flow guide sleeve and the outer wall of the refining sleeve, a hollow sleeve is arranged in the refining sleeve, a positioning step edge is arranged above the hollow sleeve and used for positioning the plurality of partition ribs of the flow guide sleeve, a flow space is kept between the upper part of the refining sleeve and the flow guide sleeve, and a refining material is arranged in the hollow sleeve.

The invention mainly applies Henry's law, a closed water storage container is arranged on the cathode side of a circular disk type electrolytic cell, when the circular disk type electrolytic cell is closed for standby, the water storage container naturally forms a space for containing, retaining and storing hydrogen and cathode water, and a check valve is arranged at a cathode water outlet in a matching manner, so that the water storage container is continuously pressurized to a set pressure (the pressure is higher than the atmospheric pressure), hydrogen molecules are compressed and forced to be re-dissolved, and the purpose of storing and improving the hydrogen molecules in the cathode water to saturated concentration is achieved.

The invention aims to provide a device for storing and improving the concentration of hydrogen molecules in cathode water, and to enable the structure of a hydrogen molecule generating system to be more perfect.

The invention arranges a cylindrical water storage container on the cathode side of the hydrogen molecule generator, the cylindrical space can obtain larger volume and contact area of gas and liquid for the whole space design, and the water storage container is internally provided with a refining kit and a flow guide kit which are arranged in concentric circles, the thinning kit is internally provided with a hollow fiber membrane, and a water outlet channel of an inner ring and an outer ring is separated between the thinning kit and the water storage container by the diversion kit, so that cathode water is upwards led into the hollow fiber membrane, and is downwards led into the hydrogen dissolving water tank from the circumference of the thinning kit after being thinned by the hollow fiber membrane, the cylinder is used as the water inlet of cathode water, which can disperse and obtain slow flow rate, therefore, the time for fusing the cathode water and the hydrogen is increased, and the water flow is guided into the hydrogen dissolving water tank from top to bottom and can generate mutual dissolution with the hydrogen above the hydrogen dissolving water tank. The pressure in the hydrogen dissolving water tank is controlled according to design requirements, so that when hydrogen molecular water is continuously produced and generated, the hydrogen dissolving water tank bears a certain pressure, and when the gas is saturated, the gas can be extruded again to pass through the hollow fiber membrane, so that the hydrogen is dissolved in the water again. When the water outlet valve is closed for standby, the water inlet pressure of the water storage container is continuously increased to a set upper limit, and at the moment, the hydrogen in the hydrogen dissolving water tank (containing the hollow fiber membrane) is compressed to form hydrogen molecules with higher concentration.

Please refer to FIG. 2A and FIG. 2B, which are comparative graphs showing that when the pressure balance is doubled, the gas concentration in the liquid is also relatively doubled according to Henry's law. Wherein: fig. 2A shows that the gas in the liquid is in a low concentration state at the time of low pressure equilibrium, and fig. 2B shows that the gas concentration in the liquid is relatively doubled according to henry's law that the gas in a high concentration is re-dissolved into the liquid over a period of time, so that the residual cathode water in the hydrogen-dissolved water tank obtains hydrogen molecules in a higher concentration.

The invention solves the problem that the front section water (about 100-200 CC residual water) of the existing flowing water type electrolytic cell hydrogen molecule water generator must be discarded due to insufficient hydrogen molecule concentration, and the applied technical means and the efficacy compared with the prior art are as follows: the cathode water outlet is provided with a check valve, when the outlet valve is closed, the hydrogen dissolving water tank forms a closed space and stores a certain pressure (the pressure is higher than the atmospheric pressure), and meanwhile, when the circular disk type electrolytic tank is standby, hydrogen is forced to be dissolved into water again. When the hydrogen molecule generator is used every other day or after a certain period of time (about 10 days), the hydrogen molecule water in the former stage (100 CC-200 CC) still maintains high concentration hydrogen molecule content.

The invention solves the problem of the decrease of the hydrogen molecule concentration of the hydrogen molecule water generator of the existing flowing water type electrolytic cell and has the following effects compared with the prior art: firstly aiming at hydrogen (H) which is not completely dissolved into hydrogen molecular water in cathode water₂) And more hydrogen is retained and contained in the water storage container (the space is a hydrogen dissolving water tank), and when the hydrogen is saturated, the hydrogen is extruded again to pass through the hollow fiber membrane to achieve the purpose of dissolving the hydrogen again, so that the concentration of hydrogen molecules in cathode water is improved.

The invention solves the problems of inconvenient space design, increased cost and decreased hydrogen molecule concentration caused by excessive extension of the pipeline because of additionally arranging the pipeline and the components in the hydrogen molecule water generator of the existing flowing water type electrolytic cell, and has the following effects compared with the prior art: because the device can generate high-concentration hydrogen molecular water without extending pipelines and other accessories, the device solves the problems of the design of the derived space of the external pipeline component of the existing electrolytic cell and the cost.

Drawings

FIG. 1 is a graph showing the relationship between the molarity (CM) of a gas dissolved in a solvent and the partial pressure (P) of the gas at a constant temperature according to Henry's law.

Fig. 2A-2B are comparative schematic diagrams showing the relative doubling of gas concentration in a liquid when the pressure balance is doubled according to henry's law.

Fig. 3 is a schematic perspective sectional view of the present invention.

FIG. 4 is a front perspective exploded view, and an enlarged view of the D and F portions of the present invention.

FIG. 5 is a bottom perspective exploded and E-section enlarged view of the present invention.

FIG. 6 is a sectional view of the present invention.

FIG. 7 is a sectional view showing the combination of cathode water and hydrogen gas when electrolysis is continuously performed according to the present invention.

Fig. 8 is a schematic sectional view taken along line B-B of fig. 7.

Fig. 9 is a schematic cross-sectional view taken along line E-E of fig. 7.

FIG. 10 is a front perspective exploded view, and an enlarged view of the R and N portions according to another embodiment of the present invention.

FIG. 11 is a bottom perspective exploded view and a K-section enlarged view of another embodiment of the present invention.

FIG. 12 is a cross-sectional view of another embodiment of the present invention.

The reference numbers are as follows:

10 … … … … molecular hydrogen water generator

11 … … … … holder

12 … … … … cover

121 … … … cathode water outlet

122 … … … flange

123 … … … external screw thread

124 … … … groove

125 … … … sleeving groove

126 … … … edge

13 … … … … lower air-collecting water-guiding disc

14 … … … … upper air-collecting water-guiding disc

15 … … … … anode electrode plate

16 … … … … cathode electrode plate

17 … … … … Ionic Membrane

18 … … … … water inlet and outlet joint

181 … … … raw water inlet joint

182 … … … anode water outlet joint

183 … … … water flow starter

19 … … … … check valve

20 … … … … water storage container

21 … … … … internal thread

22 … … … … hydrogen molecule water outlet joint

23 … … … … recess

24 … … … … locating boss

25 … … … … outlet flow path

30 … … … … diversion kit

31 … … … … lower notch

32 … … … … water outlet channel

33 … … … … locating rib

34 … … … … notch

35 … … … … partition rib

36 … … … … flow-through space

37 … … … … hydrogen dissolving water tank

40 … … … … refinement kit

41 … … … … fisheye hole

42 … … … … hollow kit

43 … … … … joining flange

44 … … … … groove

45 … … … … locating flange

46 … … … … hollow fiber membrane

47 … … … … packaging material

48 … … … … groove

A … … … … gap

Q … … … … … water stop gasket

Q1 … … … … first stagnant water packing ring

Q2 … … … … second water stop gasket

Q3 … … … … third water stop gasket

Q4 … … … … fourth water stop gasket

Detailed Description

In order to facilitate a better understanding of the invention as to its construction and its functional advantages, reference is made to the following detailed description of an embodiment thereof taken in conjunction with the accompanying drawings in which:

please refer to fig. 3, which is a schematic perspective sectional view of a three-dimensional assembly of the present invention. And FIGS. 4 and 5 are schematic diagrams showing the front and bottom stereo decomposition and the enlargement of the D, F and E parts of the present invention. And FIG. 6 is a cross-sectional schematic view of the present invention. Mainly comprises the following steps:

the hydrogen molecular water generator 10 is assembled with a lower gas collecting water guide tray 13 and an upper gas collecting water guide tray 14 inside a disc-shaped base body 11 and a cover body 12, the lower gas collecting water guide tray 13 and the upper gas collecting water guide tray 14 are provided with an anode electrode plate 15 and a cathode electrode plate 16, an ionic membrane 17 is arranged between the anode electrode plate 15 and the cathode electrode plate 16, a water inlet and outlet joint 18 is arranged outside the base body 11, the water inlet and outlet joint 18 is provided with a raw water inlet joint 181 and an anode water outlet joint 182, a cathode water outlet 121 is arranged at the center of the cover body 12 in an upward extending manner, and water is stopped between the components by a plurality of water stopping gaskets Q.

During electrolysis, raw water is introduced into the anode chamber and the cathode chamber from the anode electrode plate 15 and the cathode electrode plate 16, oxygen molecules and hydrogen molecules generated after electrolysis are separated by anode water and cathode water and respectively enter the lower gas collecting and water guiding disc 13 and the upper gas collecting and water guiding disc 14, so that the hydrogen molecules and the cathode water are led out from the cathode water outlet 121, and the oxygen molecules and the anode water are led out from the anode water outlet connector 182.

The cover 12 has a check valve 19 inside the cathode water outlet 121, a circular flange 122 is disposed outside the cover 12, an external thread 123 and a circle of groove 124 are disposed on an outer wall of the flange 122, the external thread 123 is used for locking and fixing a water storage container 20, the groove 124 is used for sleeving a first water stop gasket Q1 for water stop of the cover 12 and the water storage container 20, a diversion sleeve 30 is disposed above the flange 122, a sleeving groove 125 is disposed between the cathode water outlet 121 and the flange 122 of the cover 12 for sleeving a refining sleeve 40, a step 126 is disposed outside the cathode water outlet 121, the step 126 is used for sleeving a second water stop gasket Q2 for water stop of the cathode water outlet 121 and the refining sleeve 40.

The outer surface of the water storage container 20 is electroplated with a layer of alumina, which can effectively avoid hydrogen dissipation, the water storage container 20 is provided with an internal thread 21 corresponding to the external thread 122 of the cover 12, the internal thread 21 of the water storage container 20 is locked and fixed in the external thread 123 of the cover 12, and the first water-stop gasket Q1 is used for stopping water and sealing on the inner wall of the water storage container 20, the center of the top of the water storage container 20 is provided with a hydrogen molecule water outlet joint 22 extending upward and penetrating, so that cathode water rich in active hydrogen can be led out from the hydrogen molecule water outlet joint 22, the top surface of the water container 20 is provided with a plurality of equally divided concave portions 23 corresponding to the periphery of the hydrogen molecule water outlet joint 22, so as to form a plurality of equally divided positioning convex portions 24 on the bottom surface of the water container 20, and a water outlet flow path 25 is formed between the bottom surface of the water container 20 and the top surface of the diversion sleeve member 30.

The diversion assembly 30 is sleeved on the top surface of the flange 122 of the cover 12, the bottom of the diversion assembly 30 corresponding to the flange 122 is provided with a plurality of equally divided lower notches 31 for gas collection of hydrogen molecules and water guiding of cathode water, the outer diameter of the diversion assembly 30 is smaller than the inner diameter of the water storage container 20, thereby a water outlet channel 32 is formed on the inner wall of the water storage container 20 and the outer wall of the diversion assembly 30, the top surface of the diversion assembly 30 corresponding to the periphery of the plurality of positioning protrusions 24 is provided with a circle of positioning ribs 33, the top of the positioning ribs 33 is provided with a plurality of equally divided upper notches 34, cathode water is led into the water outlet channel 32 from the lower notches 31 and then led into the water outlet flow path 25 from the upper notches 34, the diversion assembly 30 is internally provided with a plurality of inverted L-shaped and equally-arranged partition ribs 35 around, as a positioning for the thinning assembly 40, a flow space 36 is kept between the bottom surface of the diversion assembly 30 and the top surface of the thinning assembly 40, and a hydrogen-dissolving tank 37 is disposed between the inner wall of the diversion sleeve 30 and the outer wall of the refining sleeve 40, so that cathode water can be introduced into the hydrogen-dissolving tank 37 from the circulation space 36 from top to bottom, and more hydrogen molecules are dissolved into water by utilizing the mutual dissolution phenomenon generated by the rising of hydrogen and the falling of cathode water.

A fish eye hole 41 is arranged at the center of the interior of the thinning sleeve 40 corresponding to the cathode water outlet 121, and the second water-stop washer Q2 is used for sealing the inner wall of the fish eye hole 41 in a water-stop manner, the interior of the thinning sleeve 40 is hollowed and provided with a hollow sleeve 42, a combining flange 43 is arranged at the exterior of the hollow sleeve 42 for combining the thinning sleeve 40 and the hollow sleeve 42 when the thinning sleeve 40 and the hollow sleeve 42 are integrally formed by injection molding, a circle of groove 44 is arranged at the outer wall above the hollow sleeve 42, the groove 44 can be sleeved with a third water-stop washer Q3 for water-stop of the thinning sleeve 40 and the hollow sleeve 42, a positioning step edge 45 is arranged above the hollow sleeve 42 for positioning the plurality of partition ribs 35 of the diversion sleeve 30, a thinning material is arranged inside the hollow sleeve 42, the thinning material is a hollow fiber membrane 46, and an encapsulation material 47 is used for bonding and fixing the hollow sleeve 42 above the hollow fiber membrane 46, the packaging material 47 is made of one of epoxy resin or polyurethane resin, a circle of groove 48 is disposed below the thinning sleeve 40 corresponding to the outer wall of the set of grooves 125, the groove 48 is provided with a fourth water stop gasket Q4 for stopping water on the inner walls of the thinning sleeve 40 and the set of grooves 125 of the cover 12, the hollow fiber membrane 46 is disposed below the hollow sleeve 42, a gap a is maintained between the hollow fiber membrane 46 and the bottom of the hollow sleeve 42, so that cathode water is uniformly diffused and introduced into the hollow fiber membrane 46, the aperture of the hollow fiber membrane 46 is 0.01 μm to 0.03 μm, and for thinning hydrogen molecular groups, cathode water is introduced into the flow space 36 of the flow guide sleeve 30 from bottom to top from the hollow sleeve 42, and then introduced into the hydrogen-dissolving water tank 37 from top to bottom from the flow space 36.

The invention combined by the above element structures provides a device for storing and increasing the hydrogen molecule concentration in cathode water, which is applied to practical operation:

please refer to FIG. 7, which is a cross-sectional view of the cathode water and hydrogen re-combination during continuous electrolysis. FIGS. 8 and 9 are schematic cross-sectional views B-B and E-E of FIG. 7. When the raw water flows, the raw water is introduced from the raw water inlet joint 181 of the inlet/outlet joint 18, a small portion of the water is introduced from the lower gas collecting/guiding disk 13, and flows into the anode chamber arranged radially through the anode electrode plate 15, and a large portion of the water is introduced from the upper gas collecting/guiding disk 14, and flows into the cathode chamber arranged radially through the cathode electrode plate 16.

When raw water is electrolyzed, raw water is electrolyzed in an anode chamber of the anode electrode plate 15 and a cathode chamber of the cathode electrode plate 16 respectively, so that oxygen, ozone and anode water are generated in the anode chamber, and hydrogen and cathode water are generated in the cathode chamber respectively, because the ion membrane 17 is arranged between the anode electrode plate 15 and the cathode electrode plate 16, hydrogen molecules can penetrate through the ion membrane 17 during electrolysis, oxygen molecules cannot penetrate through the ion membrane 17, and oxygen and ozone generated by the anode electrode plate 15 can be prevented from mixing into upper cathode water. The oxygen and ozone generated in the anode cavity are rapidly carried away by the anode water, and are introduced by the lower gas-collecting water-guiding plate 13, so that the oxygen and ozone can be rapidly contained above the lower gas-collecting water-guiding plate 13, thereby preventing the oxygen and ozone from mixing into the upper cathode water, and discharging the oxygen and ozone from the anode water outlet connector 182 of the water inlet/outlet connector 18 by using the anode water. Simultaneously, the nascent hydrogen generated by the cathode chamber is rapidly dissolved, combined and carried away through the cathode water, so that the hydrogen and the cathode water can be led out from the cathode water outlet 121.

After being led out from the cathode water outlet 121, the hydrogen and the cathode water are uniformly diffused from the center to the gap A on the circumference, pass through the hollow fiber membrane 46 upwards to refine the hydrogen molecular groups and filter bacteria, and then uniformly diffused from the upper circulation space 36 to the circumference, and are led into the hydrogen dissolving water tank 37 downwards, thereby dispersing and slowing down the flow velocity, increasing the time for dissolving the cathode water and the hydrogen, and the water flow is introduced into the hydrogen-dissolving water tank 36 from top to bottom, and can generate mutual dissolution with the hydrogen above the hydrogen-dissolving water tank 36, so that the cathode water rich in hydrogen molecules is firstly introduced into the water outlet channel 32 through the plurality of lower notches 31 at the circumference of the bottom of the diversion suite 30, then is introduced into the water outlet flow path 24 from bottom to top through the plurality of upper notches 34 at the circumference of the top of the diversion suite 30, and finally is led out from the hydrogen molecule water outlet joint 22 at the center of the water storage container 20.

When the outlet valve is closed and the cathode water outlet 121 is in standby state and not electrolyzed, the water container 20 is a closed space, so that the hydrogen can be stored under a certain pressure (the pressure is higher than the atmospheric pressure) to force the hydrogen to be dissolved into the water again. So that the hydrogen molecule water of the front-stage (100 CC-200 CC) still keeps high concentration hydrogen molecule content when used every other day or after a certain time (about 10 days).

Please refer to fig. 10 and 11, which show a front view, a bottom view, a three-dimensional decomposition and an enlarged schematic view of the R portion, the N portion, and the K portion of another embodiment of the present invention. FIG. 12 is a cross-sectional view of another embodiment of the present invention. Wherein: a water flow starter 183 is installed at the raw water inlet 181 of the water inlet/outlet connector 18 for calculating the raw water inlet flow rate and adjusting the working current.

In summary, the device for storing and increasing the concentration of hydrogen molecules in cathode water provided by the present invention has been actually manufactured, and has been proved to be effective in increasing the total dissolved amount of hydrogen molecules in cathode water by more than thirty percent. The invention combines the hydrogen dissolving chamber and the gas collecting chamber into a whole and thoroughly modularizes, can reduce cost, can be assembled and disassembled quickly, has the advantage of convenient after-sale service, and is expected to make a contribution to the hydrogen industry in the future. Meanwhile, the invention is the first invention which is not found in the current workshops, has industrial utilization value, is admittedly in line with the established significance of the practicability and the progress of the invention patents, and provides the intellectual property office with the application of the invention patents according to the provisions of patent laws.